Learning capable lighting equipment

ABSTRACT

A lighting device or system is configured to control of one or more parameters of light output, such as ON/OFF status, intensity when ON, color characteristics and position or orientation of light output (e.g. via a motorized luminaire control). The device or system may have other output capability, e.g. display projection or audio. Sensors or other input devices are responsive to the user. Responsive to user input, sensed activity, and/or acquired information, the device or system, controls a light source in accordance with a lighting control function. Operation of the light source and the lighting control function may be modified based on learning by the device or system.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/252,397, filed on Apr. 14, 2014, also entitled “Learning CapableLighting Equipment,” the entire disclosure of which is incorporatedherein by reference.

TECHNICAL FIELD

The present subject matter relates to techniques and equipment toprovide an interactive user interface for lighting purposes and theability to learn from user interaction, for example, to operate thelighting based on a user's profile and adjust the lighting based onphysical and/or on-line activity of the user.

BACKGROUND

Electrical lighting has become commonplace in modern society. Electricallighting devices are commonly deployed, for example, in homes, buildingsof commercial and other enterprise establishments, as well as in variousoutdoor settings. Even in a relatively small state or country, there maybe millions of lighting devices in use.

Traditional lighting devices have tended to be relatively dumb, in thatthey can be turned ON and OFF, and in some cases may be dimmed, usuallyin response to user activation of a relatively simple input device.Lighting devices have also been controlled in response to ambient lightdetectors that turn on a light only when ambient light is at or below athreshold (e.g. as the sun goes down) and in response to occupancysensors (e.g. to turn on light when a room is occupied and to turn thelight off when the room is no longer occupied for some period). Oftentraditional lighting devices are controlled individually or asrelatively small groups at separate locations.

With the advent of modern electronics has come advancement, includingadvances in the types of light sources as well as advancements innetworking and control capabilities of the lighting devices. Forexample, solid state sources are now becoming a commercially viablealternative to traditional light sources such as incandescent andfluorescent lamps. By nature, solid state light sources such as lightemitting diodes (LEDs) are easily controlled by electronic logiccircuits or processors. Electronic controls have also been developed forother types of light sources. As increased processing capacity finds itsway into the lighting devices, it becomes relatively easy to incorporateassociated communications capabilities, e.g. to allow lighting devicesto communicate with system control elements and/or with each other. Inthis way, advanced electronics in the lighting devices as well as theassociated control elements have facilitated more sophisticated lightingcontrol algorithms as well as increased networking of lighting devices.

However, there have also been proposals to further enhance lightingcontrols. For example, it has been proposed that a lighting device mayinclude a sensor and processing capability to detect gestural inputsfrom a user. If the sensor detects touch, the user must approach thedevice or an associated control panel and contact the touch sensor in anappropriate manner to input a gesture corresponding to the user'sdesired control of the light. More recent developments in gesturalsensing technologies eliminate the need for actual touching, but suchdevices still typically require that the user make the appropriategesture in fairly close proximity to the sensor on the device or at thecontrol panel.

There have also been efforts to develop speech-command responsivecontrol of lighting, using advanced speech recognition technologies.

In a somewhat related field a variety of entities are proposing controlsfor lighting and other functions in a building from a variety ofportable user devices, for example, from remote controls or from mobiledevices such as smartphones or tablet computers.

Despite such recent efforts, there is still room for further improvementin the user interface with a lighting system and/or in the functionsthat a lighting system may offer through its user interface as well asthe ability to learn and adjust a lighting system based on past andcurrent user interaction.

SUMMARY

An example of a system described in detail below includes a source oflight, a sensor, a data communication interface, a storage device and aprocessor. In this system example, the source of light outputs visiblelight responsive to control by the processor, and the data communicationinterface is controlled by the processor. The sensor is configured todetect a condition in a space illuminated by the system related to anactivity of at least one of a plurality of occupants of the space andthe sensor provides a condition responsive input to the processor.

The storage device in this system example contains a program that, whenexecuted by the processor, configures the system to identify at leastone of the plurality of occupants and, for each of the identifiedoccupants, retrieve a profile of the identified occupant including alighting control function and operate the light source in accordancewith the lighting control function while the identified occupant is inthe space. Execution of the program by the processor also configures thesystem to access information about each identified occupant from anon-line service to determine an on-line status and process the conditionresponsive input to determine an activity of each identified occupant inthe space. Based on the on-line status and/or activity status of eachidentified occupant, execution of the program by the processor adjuststhe operation of the light source. In this example, operation andadjustment of the light source for each identified occupant contributesto a composite operation and a composite adjustment of the light sourcein accordance with a composite lighting control function.

Still another example of a system described in detail below includes asource of light, a sensor, a storage device and a processor. In thissystem example, the source of light outputs visible light responsive tocontrol by the processor. The sensor is configured to detect a conditionin a space illuminated by the system related to an activity of at leastone of a plurality of occupants of the space and the sensor provides acondition responsive input to the processor. This system also includes auser input element for providing user input for processing to theprocessor.

The storage device in this system example contains a program that, whenexecuted by the processor, configures the system to identify theoccupant and operate the light source in accordance with a predeterminedlighting control function while the occupant is in the space. Executionof the program by the processor also configures the system to receiveinput from at least one of the user input element representing a desiredchange of the visible light output and the sensor representing anactivity status of the identified occupant. In response to the receivedinput, the predetermined lighting control function is modified and themodified lighting control function is stored as a profile establishedfor the identified occupant. While the identified occupant remains inthe space, the light source is operated in accordance with the modifiedlighting control function of the profile.

Additional objects, advantages and novel features of the examples willbe set forth in part in the description which follows, and in part willbecome apparent to those skilled in the art upon examination of thefollowing and the accompanying drawings or may be learned by productionor operation of the examples. The objects and advantages of the presentsubject matter may be realized and attained by means of themethodologies, instrumentalities and combinations particularly pointedout in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawing figures depict one or more implementations in accord withthe present concepts, by way of example only, not by way of limitations.In the figures, like reference numerals refer to the same or similarelements.

FIG. 1 is a simple example of a learning system with lighting controlbased on a range of inputs, including a range of previous outputs,historical data and a machine learning algorithm.

FIG. 2 is another example of the learning system of FIG. 1 with threeinputs, including a previous output, historical data and a machinelearning algorithm where the output controls a lighting function.

FIG. 3 is a graph depicting an example of a preset lighting controlfunction.

FIG. 4 is a graph depicting an example of the preset lighting controlfunction of FIG. 3 with a manual user adjustment to the lighting controlfunction.

FIG. 5 is a graph depicting an example of the preset lighting controlfunction of FIG. 3 with two manual user adjustments to the lightingcontrol function.

FIG. 6 is a graph depicting an example of a learned lighting controlfunction based on various manual user adjustments to the preset lightingcontrol function.

FIG. 7A is a functional block diagram of a simple example of a systemhaving intelligent lighting devices, at least some of which includecomponents and are configured to implement an interactive userinterface.

FIG. 7B is a functional block diagram of an example of an intelligentlighting device that may be used in the system of FIG. 7A.

FIG. 8 is a functional block diagram of an example human/machine userinterface that may be implemented by the system of FIG. 7A.

FIG. 9 is a flow chart of an example process to implement lighting withthe system of FIG. 7A using the learning system of FIG. 1.

FIG. 10 is a flow chart of another example process to implement lightingwith the system of FIG. 7A using the learning system of FIG. 1.

FIG. 11 is a flow chart of still another example process to implementlighting with the system of FIG. 7A using the learning system of FIG. 1.

FIG. 12 is a is a simplified functional block diagram of a computer thatmay be configured as a host or server, for example, to function as theexternal server or a server if provided at the premises in the system ofFIG. 7A.

FIG. 13 is a simplified functional block diagram of a personal computeror other user terminal device, which may be used as the remote accessterminal, in the system of FIG. 7A.

FIG. 14 is a simplified functional block diagram of a mobile device, asan alternate example of a user terminal device, for possiblecommunication in or with the system of FIG. 7A.

DETAILED DESCRIPTION

In the following detailed description, numerous specific details are setforth by way of examples in order to provide a thorough understanding ofthe relevant teachings. However, it should be apparent to those skilledin the art that the present teachings may be practiced without suchdetails. In other instances, well known methods, procedures, components,and/or circuitry have been described at a relatively high-level, withoutdetail, in order to avoid unnecessarily obscuring aspects of the presentteachings.

As lighting devices incorporate more intelligence, people are beginningto add more functionality, such as more sophisticated userinteractivity. The world is becoming interconnected. The trend intechnologies that control lighting is toward an “Internet of things” inwhich more and more machines are interconnected to communicate with eachother and interact with the users via the Internet. However, there aremany diverse ways to access the Internet, for example, with a computervia wired or fiber network (even with a WiFi local link) or with amobile device (e.g. smartphone or tablet) via any of the variousavailable public and private wireless networks.

For lighting, the lighting devices and controllers and possibly somecentral control element (e.g. a server) may communicate with each othervia a network. The user in turn communicates with such a system via theInternet using one of these common access techniques instead of or inaddition to interaction via system elements (e.g., a control panel,sensor, etc.) in the illuminated space. So, the user often now is comingin from another network that may be separate from the networking usedfor communications of the lighting system elements. The user also hastheir own device, albeit of their choosing, but separate and in additionto the elements of the lighting system. Such user access may be part ofthe problem. For example, use of other access technologies adds to thecomplexity of the system; and the integration of the lighting networkwith other user devices, may entail use of separate user deviceprogramming in addition to special programming in the lighting system,and/or may increase overall costs. In some cases, the additional devicesand/or their software may not be adequately adapted to the lightingsystem and its operations.

To improve the user experience and provide a more effective or moreefficient user interface, the various examples of a lighting systemdiscussed below and shown in the drawings offer an interactive userinterface implemented with the input and/or output components andassociated processing functionality in one or more of the lightingdevices. Stated another way, the lighting devices may themselvesimplement some or all of the interactive user interface to the lightingsystem, and the user interacts with the lighting system via the lightingdevices.

Furthermore, the various examples of a lighting system discussed belowand shown in the drawings offer responsive lighting conditions based onuser activity and user conditions. That is, not only does the lightingsystem respond to an interactive user interface, but the lighting systemalso responds to other conditions both sensed from within a spaceoccupied by the user as well as acquired from outside of the space, thuslearning from these other conditions. Over time, some of these learnedinputs may be used to adjust future lighting or other controlledconditions.

Reference now is made in detail to the examples illustrated in theaccompanying drawings and discussed below.

FIG. 1 illustrates a simple example of a learning system 100 that may beused to control a lighting function of an adjustable lighting device 11,such as one or more fixtures, lamps or other types of luminairesdescribed in greater detail below. The learning system 100 receivesvarious inputs 1A, 1B . . . 1N, including previously generated outputs7A, 7B . . . 7K and generates the current outputs 7A, 7B . . . 7K. Thesevarious inputs include, for example, user selectable options (i.e.,direct user input), sensed conditions (e.g., indirect user input basedon user activity, other non-user activity, or other conditions such astime of day, temperature, weather conditions, etc.). Inputs may alsoinclude information obtained via external network communications, suchas user inputs via a remote device or status or the like about a useroccupant obtained from an on-line service. The outputs correspond to,for example, a variety of light output parameters, such as ON/OFF,intensity (when ON) and various color-related characteristics, which maychange or vary the output of lighting device 11 in response to a controlsignal or command from the system 100.

The learning system 100 includes a variable history 3, commonly referredto as a data set. The variable history (data set) 3 includes not onlythe currently received various inputs 1A, 1B, 1N and outputs 7A, 7B . .. 7K, but also all previously received inputs and outputs. Forpersonalized control, the data set becomes part of or is linked to aprofile of a particular user who may occupy the space from time to time.

This variable history (data set) 3 is provided to a machine learningalgorithm 5 which in turn generates the outputs 7A, 7B . . . 7K. Themachine learning algorithm 5 is, for example, a neural network that“learns” how to manipulate the various inputs, including previouslygenerated outputs, in order to generate current outputs. As part of this“learning” process, the neural network calculates weights to beassociated with the various inputs, including the previously generatedoutputs. The weights are then utilized by the neural network tomanipulate the inputs, including the previously generated outputs, andgenerate the current outputs. Although FIG. 1 illustrates a simpleexample of the learning system 100, such learning system 100 may be moreor less complex, including any number of inputs and outputs with avariable history (data set) 3 that may be filtered or otherwisecontrolled and any number of different learning algorithms 5. Hardwarefor receiving the inputs, storing the data set and running the learningalgorithm to control the lighting device will be discussed later.

For simplicity, FIG. 2 is an example of the learning system 100 of FIG.1 with three inputs (two inputs and a previous output) that generatesone output. Although a variety of light output parameters may becontrolled, the example of lighting device 11 in the discussions belowis controlled to adjust the correlated color temperature (CCT) of thelight output. In this example, input 1A is a manual user adjustment ofthe CCT of adjustable lighting device 11. The color temperature of alamp or other light source is the temperature of an ideal black bodyradiator that radiates light of comparable hue to that of the lamp orother light source. Color temperature is conventionally stated in Kelvin(K). CCT is the color temperature of a black body radiator which tohuman color perception most closely matches the light from the lamp orother light source. Thus, in this example, the user is attempting tochange the CCT of adjustable lighting device 11. Input 1B is the time ofday corresponding to the manual user adjustment. The output 7A is theCCT that will be applied to adjustable lighting device 11.

In the example of FIG. 2, the data set 3 includes all previous manualuser adjustments of CCT as well as the time of day corresponding to eachmanual user adjustment. The machine learning algorithm 5 takes the dataset 3 and generates a current CCT value 7A to be applied to adjustablelighting device 11. In this way, the learning system 100 “learns” fromcurrent and previous manual CCT adjustments by the user such that thelearning system 100, for example, anticipates future CCT adjustments.Stated another way, learning system 100 may automatically adjust the CCTof adjustable lighting device 11 based on a current time of day in lightof previous similar CCT adjustments made by the user. As such, the CCTof adjustable lighting device 11 is, for example, adjusted to meet auser's needs and desires without requiring any user intervention toeffect the change.

FIG. 3 illustrates a graph of a preset lighting control function, inthis example, related to the CCT of a light source (e.g., adjustablelighting device 11) whenever ON during a 24-hour cycle. In this graph,the x axis represents the CCT level, in K, and the y axis represents thetime of day, in hourly increments. The preset lighting control function,for example, adjusts the CCT or color temperature of a lighting device,such as adjustable lighting device 11. As depicted in the graph, thepreset lighting control function sets the CCT to 5,000 K, a cool white,at approximately 5:00 AM. Then, throughout the day, the preset lightingcontrol function adjusts the CCT until it reaches 3,000 K, a warm white,at approximately 4:30 PM. The preset lighting control function maintainsthe CCT at 3,000 K until approximately 5:00 AM the next morning, whenthe cycle repeats itself. In this way, the preset lighting controlfunction, for example, replicates variations in color characteristics ofdaylight throughout the daytime working hours of each day and a steadyselected CCT (e.g., 3,000 K) at other times.

FIG. 4 illustrates a graph of the preset lighting control function,depicted in FIG. 3, as well as a manual user adjustment. Atapproximately 9 AM, in this example, a user adjusts the CCT of thelighting device 11. Such user adjustment, however, only remainseffective for a single time cycle (i.e., one hour in the example). Atapproximately 10 AM, in this example, the preset lighting controlfunction returns to adjusting the CCT in accordance with the presetschedule. Although not explicitly shown in FIG. 4, such user adjustment,for example, becomes input 1A of the learning system 100 in FIG. 2; andthe time of day at which the user adjustment was made, for example,becomes input 1B. In addition, the current CCT of lighting device 11just prior to the user adjustment, for example, becomes output 7A as theadditional input in FIG. 2. These three input values (i.e., useradjustment, time of day, and current CCT) become part of the data set 3and flow into the machine learning algorithm 5, which influences theactual CCT value of lighting device 11 in response to the useradjustment.

Although FIG. 4 depicts the learning system 100 influencing the CCTvalue of lighting device 11 in response to the manual user adjustment asa single occurrence, such single occurrence is stored as part of thedata set 3 of learning system 100. As a result, at approximately 9 AM onsubsequent days, the learning system 100 will, for example, influencethe actual CCT value of lighting device 11 in accordance with theprevious manual user adjustment. Thus, the data set 3 begins to define amodified lighting control function in contrast to the original (or‘default’) preset lighting control function.

FIG. 5 illustrates a graph of the preset lighting control function andthe modified lighting control function based on the first useradjustment of FIG. 4 as well as a second manual user adjustment.Although such second manual user adjustment may be made on the same dayas the first user adjustment, for clarity, it is assumed that FIG. 4represents a previous day and FIG. 5 represents a subsequent day suchthat the second manual user adjustment is made on a later day than thefirst user adjustment. Thus, at approximately 9 AM, the learning system100, based on data set 3 including the first manual user adjustment ofFIG. 4, influences the adjustment of the CCT of lighting device 11.Furthermore, at approximately 11 AM, in this example, the user againadjusts the CCT of lighting device 11. This second user adjustment alsoonly remains effective for a single time cycle (i.e., one hour) and thenthe preset lighting control function returns to adjusting the CCT. Aswith FIG. 4, although not explicitly shown, this second user adjustment,the time of day of the adjustment, and the current CCT prior to theadjustment are all fed into the learning system 100 of FIG. 2. In thisway, the second set of inputs also become part of the data set 3 andflow into the machine learning algorithm 5, which further influences theactual CCT value of lighting device 11 in response to the useradjustment. In addition, as described above, this additional occurrenceof a manual user adjustment stored in the data set 3 further defines themodified lighting control function.

Over time (e.g., several days to a few weeks), various user adjustmentswill be made at various times throughout each day. Each additionaloccurrence of a manual user adjustment not only influences the lightingdevice 11 adjustment at that time, but also further defines the modifiedlighting control function. FIG. 6 illustrates a graph of the presetlighting control function and the modified lighting control functionbased on these various user adjustments. As described above in relationto FIGS. 4-5, these various user adjustments are additional inputs toand add to the data set 3 of the learning system 100 of FIG. 2. Based onthe expanded data set 3 and “learning” by the machine learning algorithm5, a “learned” modified lighting control function, depicted by a solidlight curved line in FIG. 6, that more closely matches the various useradjustments replaces the preset lighting control function, depicted by adashed line in FIG. 6. In this way, adjustable lighting device 11 is,for example, operated in accordance with the modified lighting controlfunction that learns from user interaction and adjusts operations basedon user activity.

In some situations, each occurrence of a manual user adjustment may bedistinct and not overlap with any other occurrence (i.e., a 9 AMadjustment, a 10 AM adjustment and a 2 PM adjustment). In thesesituations, the modified lighting control function is simply thecollection of all manual user adjustments. In other situations, however,user adjustments may occur in such a way that multiple occurrencesoverlap (e.g., a 9 AM Monday adjustment that is different from a 9 AMWednesday adjustment). First, it should be noted that the day of theweek would represent an additional input that could be stored in dataset 3 and further influence both the current output as well as themodified lighting control function. As discussed above, learning system100 may be designed with any number of inputs (as well as any number ofoutputs) in order to capture the necessary complexity of the task. Asdescribed in greater detail below, such inputs may include not onlydirect user input, but also indirect user interaction as well as otherconditions sensed from within a space and/or acquired elsewhere. Inaddition, learning system 100 may be designed with any one or somecombination of machine learning algorithm(s) 5. It is this machinelearning algorithm 5 that defines how such overlapping occurrences willbe combined to influence any given output and the modified lightingcontrol function. In one simple example based on the system 100 of FIG.2, learning algorithm 5 performs a “best fit” to form a function and/orcurve based on the user inputs (e.g., sum all overlapping adjustmentsand divide by the number of overlapping adjustments to determine anaverage adjustment).

The learning techniques like those outlined above may be implemented inor control a single lighting device or in a system controlling a few ora substantial number of lighting devices. Even a single standalonedevice, however, may be network connected if the device is intended touse remote data sources as one or more of the inputs. For discussionpurposes, however, we will next consider a system of devices thatprovides lighting services throughout a premises.

FIG. 7A illustrates an example of a system 10, that may utilize thelearning system 100 to control a number of lighting devices 11 at apremises 21, in block diagram form. The illustrated example of thesystem 10 includes a number of adjustable lighting devices 11, such asfixtures or lamps or other types of luminaires. Control of such lightingdevices 11 is, for example, based on identifying one or more occupantsof a room or other space within premises 21 and operating the lightingdevices 11 in accordance with a corresponding profile of each identifiedoccupant. As described above and further below, such correspondingprofile may be learned via learning system 100. Several differentconfigurations of the lighting devices 11 are shown by way of examples.The represented differences amongst the examples of devices 11 will bediscussed more fully later.

The term “lighting device” as used herein is intended to encompassessentially any type of device that processes power to generate light,for example, for illumination of a space intended for use of oroccupancy or observation, typically by a living organism that can takeadvantage of or be affected in some desired manner by the light emittedfrom the device. However, a lighting device 11 may provide light for useby automated equipment, such as sensors/monitors, robots, etc. that mayoccupy or observe the illuminated space, instead of or in addition tolight provided for an organism. A lighting device 11, for example, maytake the form of a lamp, light fixture or other luminaire thatincorporates a source, where the source by itself contains nointelligence or communication capability (e.g. LEDs or the like, or lamp(“regular light bulbs”) of any suitable type). Alternatively, a fixtureor luminaire may be relatively dumb but include a source device (e.g. a“light bulb”) that incorporates the intelligence and communicationcapabilities discussed herein. In most examples, the lighting device(s)11 illuminate a service area to a level useful for a human in or passingthrough the space, e.g. regular illumination of a room or corridor in abuilding or of an outdoor space such as a street, sidewalk, parking lotor performance venue. However, it is also possible that one or morelighting devices 11 in or on a particular premises 21 served by a system10 have other lighting purposes, such as signage for an entrance or toindicate an exit. Of course, the lighting devices 11 may be configuredfor still other purposes, e.g. to benefit human or non-human organismsor to repel or even impair certain organisms or individuals.

Each respective adjustable lighting device 11 includes a light source13, a communication interface 15 and a processor 17 coupled to controlthe light source 13. The light sources may be virtually any type oflight source suitable to providing illumination that may beelectronically controlled. The light may be of the same general type inall of the lighting devices, e.g. all formed by some number of lightemitting diodes (LEDs); although in many installations, some number ofthe lighting devices 11 may have different types of light sources 13.

The processor 17 also is coupled to communicate via the interface 15 andthe network link with one or more others of the lighting devices 11 andis configured to control operations of at least the respective lightingdevice 11. The processor may be implemented via hardwired logiccircuitry, but in the examples, the processor 17 is a programmableprocessor such as a central processing unit (CPU) of a microcontrolleror a microprocessor. Hence, in the example of FIG. 7A, each lightingdevice 11 also includes a memory 19, storing programming for executionby the processor 17 and data that is available to be processed or hasbeen processed by the processor 17. The machine learning algorithm 5 anddata set 3 of FIG. 2, as well as a learned profile of each identifiedoccupant, are examples of such programming and data stored in memory 19for execution and processing by processor 17. The processors andmemories in the lighting devices may be substantially the samethroughout the devices 11 throughout the premises, or different devices11 may have different processors 17 and/or different amounts of memory19, depending on differences in intended or expected processing needs.

In the example, each lighting device has the processor, memory,programming and data set to implement the learning and related controlfunctions under consideration here. These elements, programming, dataand functions, however, may be arranged in a system in other ways. Forexample, in each area of a premises, one lighting device may beconfigured as a ‘leader’, to perform learning and high level control,and provide instructions to some number of other ‘follower’ lightingdevices serving the particular area. Another approach might distributesome of the processing on a shared bases across some number of thelighting devices.

Returning to the specific examples, the intelligence (e.g. processor 17and memory 19) and the communications interface(s) 15 are shown asintegrated with the other elements of the lighting device or attached tothe fixture or other element that incorporates the light source.However, for some installations, the light source may be attached insuch a way that there is some separation between the fixture or otherelement that incorporates the electronic components that provide theintelligence and communication capabilities. For example, thecommunication component(s) and possibly the processor and memory (the‘brain’) may be elements of a separate device or component coupledand/or collocated with the light source 13.

In our example, the system 10 is installed at a premises 21. The system10 also includes a data communication network 23 that interconnects thelinks to/from the communication interfaces 15 of the lighting devices11, so as to provide data communications amongst the intelligentlighting devices 11. Such a data communication network 23 also isconfigured to provide data communications for at least some of thelighting devices 11 via a data network 25 outside the premises, shown byway of example as a wide area network (WAN), so as to allow devices 11or other elements/equipment at the premises 21 to communicate withoutside devices such as the server/host computer 27 and the userterminal device 29. The wide area network 25 outside the premises, maybe an intranet or the Internet, for example.

The premises 21 may be any location or locations serviced for lightingand other purposes by a networked intelligent lighting system of thetype described herein. The lighting devices 11 are located to providelighting service in various areas in or about the premises 21. Most ofthe examples discussed below focus on building installations, forconvenience, although the system may be readily adapted to outdoorlighting. Hence, the example of system 10 provides lighting and possiblyother services in a number of service areas in or associated with abuilding, such as various rooms, hallways, corridors or storage areas ofa building and an outdoor area associated with a building. Any buildingforming or at the premises 21, for example, may be an individual ormulti-resident dwelling or may provide space for one or more enterprisesand/or any combination of residential and enterprise facilities.

The lighting devices 11, as well as any other equipment of the system orthat uses the network 23 in the service areas of the premises 21,connect together with and through the network links and any other mediaforming the communication network 23. For lighting operations, thelighting devices 11 (and other system elements if any) for a givenservice area are coupled together for network communication with eachother through data communication media to form a portion of a physicaldata communication network. Similar elements in other service areas ofthe premises are coupled together for network communication with eachother through data communication media to form one or more otherportions of the physical data communication network at the premises 21.Local communication over the network, for example, enables some numberof lighting devices serving a room or other area to coordinate useridentifications, input processing, learning and light source control,e.g. to provide coordinated illumination of the particular space.

The communication interface 15 in each lighting device 11 in aparticular service area will be of a physical type and configured tooperate in a manner that is compatible with the physical media andelectrical protocol(s) implemented for the particular service areaand/or throughout the premises 23. Although the communication interfaces15 are shown communicating to/from the network cloud via lines, such aswired links or optical fibers; some or all of the interfaces 15 may usewireless communications media such as optical or radio frequencywireless communication. Also, although the examples in FIG. 7A show mostof the lighting devices 11 having one communication interface, some orall of the lighting devices 11 may have two or more communicationsinterfaces to enable data communications over different media with thenetwork(s) and/or with other devices in the vicinity.

The various portions of the network in the service areas in turn arecoupled together to form a data communication network at the premises,for example to form a premises-wide local area network (LAN) or thelike. The overall premises network, generally represented by the cloud23 in the drawing, encompasses the data links to/from individual devices11 and any networking interconnections within respective areas of thepremises where the devices 11 are installed as well as the LAN or otherpremises-wide interconnection and associated switching or routing. Inmany installations, there may be one overall data communication network23 at the premises 21. However, for larger premises and/or premises thatmay actually encompass somewhat separate physical locations, thepremises-wide network may actually be built of somewhat separate butinterconnected physical networks represented by the dotted line clouds.The LAN or other data network forming the backbone of system network 23at the premises 21 may be a data network installed for other datacommunications purposes of the occupants; or the LAN or otherimplementation of the network 23, may be a data network of a differenttype installed substantially for lighting system use and for use by onlythose other devices at the premises that are granted access by thelighting system elements (e.g. by the lighting devices 11).Communications amongst devices serving different areas of the premises,for example, may enable communication of some relevant input data,enable device(s) in one area to obtain a user profile from a device inanother area, and/or support a distributed implementation of some or allof the relevant processing.

Hence, there typically will be data communication links within a room orother service area as well as data communication links from the lightingdevices 11 in the various rooms or other service areas out to widernetwork(s) forming the data communication network 23 or the like at thepremises 21. Devices 11 within a service area can communicate with eachother, with devices 11 in different rooms or other areas, and in atleast some cases, with equipment such as 27 and 29 outside the premises21. For example, server 27 implements an on-line service and device(s)11 and/or system 10 communicate with server 27 to determine a status ofan identified occupant for the on-line service.

Various network links within a service area, amongst devices indifferent areas and/or to wider portions of the network 23 may utilizeany convenient data communication media, such as power lines wiring,separate wiring such as coax or Ethernet cable, optical fiber,free-space optical, or radio frequency wireless (e.g. Bluetooth orWiFi); and a particular premises 21 may have an overall data network 23that utilizes combinations of available networking technologies. Some orall of the network communication media may be used by or made availablefor communications of other gear, equipment or systems within thepremises 21. For example, if combinations of WiFi and wired or fiberEthernet are used for the lighting system communications, the WiFi andEthernet may also support communications for various computer and/oruser terminal devices that the occupant(s) may want to use in thepremises. The data communications media may be installed at the time aspart of installation of the lighting system 10 at the premises 21 or mayalready be present from an earlier data communication installation.Depending on the size of the network 23 and the number of devices andother equipment expected to use the network 23 over the service life ofthe network 23, the network 23 may also include one or more packetswitches, routers, gateways, etc.

In addition to a communication interface 15 for enabling a lightingdevice to communicate via the network 23, some of the devices 11 mayinclude an additional communication interface, shown as a wirelessinterface 15W in the lighting device 11B. The additional interfaceallows other elements or equipment, such as a host computer or serverlike 27, to access the communication capabilities of the system 10, forexample, as an alternative user interface access or for access throughthe system 10 to the WAN 25.

A host computer or server like 27 can be any suitable network-connectedcomputer, tablet, mobile device or the like programmed to implementdesired network-side functionalities. Such a device may have anyappropriate data communication interface to link to the WAN 25.Alternatively or in addition, a host computer or server similar to 27may be operated at the premises 21 and utilize the same networking mediathat implements data network 23 directly and/or via an additionalcommunication interface such as wireless interface 15W in lightingdevice 11B.

The user terminal equipment such as that shown at 29 may be implementedwith any suitable processing device that can communicate and offer asuitable user interface. The terminal 29, for example, is shown as adesktop computer with a wired link into the WAN 25. However, otherterminal types, such as laptop computers, notebook computers, netbookcomputers, and smartphones may serve as the user terminal computers.Also, although shown as communicating via a wired link from the WAN 25,such a user terminal device may also or alternatively use wireless oroptical media; and such a device may be operated at the premises 21 andutilize the same networking media that implements data network 23directly and/or via an additional communication interface such aswireless interface 15W in lighting device 11B.

For various reasons, the communications capabilities provided at thepremises 21 may also support communications of the lighting systemelements with user terminal devices, control panels, standalone sensorsand/or computers (not shown) within the premises 21. The user terminaldevices and/or computers within the premises may use communicationsinterfaces and communications protocols of any type(s) compatible withthe on-premises networking technology of the system 10. Suchcommunication with a user terminal, for example, may allow a person inone part of the premises 21 to communicate with a lighting device 11 inanother area of the premises 21, to obtain data therefrom and/or tocontrol lighting or other system operations in the other area.

The external elements, represented generally by the server/host computer27 and the user terminal device 29, which may communicate with theintelligent elements of the system 10 at the premises 21, may be used byvarious entities and/or for various purposes in relation to operation ofthe lighting system 10 and/or to provide information or other servicesto users within the premises 21, e.g. via the interactive user interfaceportal offered by the lighting devices 11.

Returning now to the lighting devices 11, in the example of the system10, at least one of the lighting devices 11 includes a user input sensorconfigured to detect user activity related to user inputs withoutrequiring physical contact of the user; and at least one of the lightingdevices 11 includes an output component configured to provideinformation output to the user. The drawings show several differentexamples of these input/output elements.

By contrast, some of the lighting devices 11 may not have user interfacerelated elements. In the example of system 10 in FIG. 7A, each of thelighting devices 11A includes a light source 13, a communicationinterface 15 linked to the network 23 and a processor 17 coupled tocontrol the light source 13 and to communicate via the interface 15 andthe link to network 23. Such devices 11A may include lighting relatedsensors (not shown), such as occupancy sensors or ambient light color orlevel sensors; but the intelligent lighting devices 11A do not includeany user interface components, for user input or for output to a user(other than control of the respective light source 13). The processorsof devices 11A are configured (e.g. programmed in our example) tocontrol lighting operations, for example, to control the light sources13 of such devices 11A in response to commands received via the network23 and the interfaces 15. The processors of devices 11A are alsoconfigured, for example, with the machine learning algorithm 5 of FIG. 2such that the processors of devices 11A learn from the controlledlighting operations.

For purposes of discussion, the drawing (FIG. 7A) shows three examplesof lighting devices 11B, 11C and 11D that have one or more userinterface components. Although three examples are shown, it is envisagedthat still other types of interface components and/or arrangementsthereof in various lighting devices may be used in any particularimplementation of a system like the system 10 of FIG. 7A; and the latermore detailed example of FIG. 7B shows a device that incorporates acombination of several different user input and output components.Furthermore, although the examples depict user interface componentsintegrated within lighting device 11, such interface components mayalternatively and/or additionally be implemented as standalone elementsof or within other devices of system 10 and communications via thenetwork(s), as discussed further below. Any one lighting device thatincludes components to support the interactive user interfacefunctionality of the system 10 may include an input sensor type userinterface component, an output type user interface component, or acombination of one or more input sensor type user interface componentswith one or more output type user interface components.

Although the various sensors are referred to generally as user inputsensors and may include any combination of user interface components,such user input and/or user interface need not necessarily requiredirect user activity or direct interactivity with the light device 11.As described in greater detail below, the user activity referred toherein may be user interaction directly with the lighting device 11intended to control a lighting function (e.g., the user deliberatelyintends to turn the light off or otherwise change a light or othercontrol setting and gestures to the device to effect such change), theuser activity may be interaction directly with other aspects of thespace and indirectly with the lighting device 11 for control purposes(e.g., the user interacts with a terminal device within the space andthe lighting device 11, based on task recognition and learned userpreferences, adjusts operations accordingly), and/or the user activitymay somewhat unintentionally interact with, and thus indirectly control,the lighting device 11 and/or system 10 (e.g., the user intentionallydrinks a cup of tea when the user typically drinks a cup of coffee,unintentionally indicating a different mood of the user to the lightingdevice 11, which adjusts operations accordingly). An agitatedconversation may be deliberate in a general sense, but not intended as aspecific command to the system 10 to change a control setting; yet thesystem 10 may detect the agitated conversation as an indication of moodand respond by adjusting lighting and/or other environmental conditionsin the occupied space.

With reference to FIG. 7A, each of some number of intelligent lightingdevice 11B at the premises 21 includes one or more sensors 31 (two inthe illustrated example). The lighting devices 11B can be in one or morerooms or other service areas at the premises 21. In the intelligentlighting devices 11B, each of the sensors 31 is configured for detectionof intensity of received light and to support associated signalprocessing to determine direction of incident light. A particularexample of a sensor 31 that can be used as an input device fordetermining direction and intensity of incident light received by thesensor 31 is a quadrant hemispherical light detector or “QHD” (see e.g.U.S. Pat. Nos. 5,877,490 and 5,914,487). The sensors 31 may detect lightin some or all of the visible portion of the spectrum or in otherwavelength bands, such as infrared (IR) or ultraviolet (UV). By usingtwo or more such sensors 31 in the same or a different lighting device11B illuminating the same service area, it is possible to detectposition of an illuminated point or object in three-dimensional spacerelative to known positions of the sensors 31. By detecting position ofone or more points over time, it becomes possible to track motion withinthe area illuminated by the device(s) 11B and monitor for user input bythe sensors 31, for example, as a gestural user input or when a usertransitions from location for one typical type of task to location foranother type of task (e.g., transitioning from reviewing documents on adesk to interacting with a computer on the desk). Detection of rapidmotion (e.g., pacing or hand gestures) may provide another technique todetect agitation of the occupant. Although two sensors 31 are shown onone lighting device 11B; there may be more sensors 31 in a lightingdevice 11B, or there may be a single sensor 31 in each device 11Bamongst some number of the lighting devices 11B illuminating aparticular service area of the premises 21.

In the example, at least one of the devices 11B also includes a lightingrelated sensor 33. Although shown in device 11B for purposes ofdiscussion and illustration, such a sensor may be provided in any of theother lighting devices 11, in addition or as an alternative todeployment of the sensor 33 in a lighting device 11B. Examples of suchlighting related sensor 33 include occupancy sensors, device output(level or color characteristic) sensors and ambient light (level orcolor characteristic) sensors. The sensor 33 may provide a conditioninput for general lighting control, e.g. to turn on-off devices 11and/or adjust light source outputs. However, the sensor inputinformation from sensor 33 also or alternatively may be used as anotherform of user input, for example, to refine detection and trackingoperations responsive to signals from the sensors 31.

In an example of a user input related function, the signals from thesensors 31 in lighting devices 11B illuminating a particular room withinpremises 21 are processed to detect gestures of one or morepersons/users within the room. The lighting output from sources 13 ofthe devices 11 illuminating the area may be controlled responsive to thedetection of one or more predetermined user input gestures based on userprofile(s) and/or a learned control function. Alternatively, or inaddition to gestural input, the signals from the sensors 31 areprocessed to detect a task or other activity of one or morepersons/users within the room. The lighting output from sources 13 ofthe devices 11 illuminating the area may be controlled responsive to thedetection of one or more predetermined or learned user input activitiesor task(s) based on the user's profile and/or learned control function.Although not shown, one or more of the lighting devices 11B may alsoinclude a user output component, for example to provide an audio orvideo output of information to the person or persons in the room.

Such gesture or user activity input together with lighting control andother information output implement a form of interactive user interface.This interface related operation includes selectively controlling alighting operation of at least some number of the lighting devices as afunction of a processed user input. The interface related operation mayalso include either control of a non-lighting-related function as afunction of a processed user input, or an operation to obtain andprovide information as a response to a user input as an output via theoutput component.

In the example of system 10, each of the intelligent lighting devices11C and/or one or more of the lighting devices 11D in one or more roomsor other service areas of the premises 21 support audio input and audiooutput, for an audio based user interface functionality. These inputcomponents may be provided in different lighting devices 11 than thosedeploying the output elements. Also, audio user interface components maybe provided in different lighting devices 11 than those deploying thevideo user interface components. For convenience, the audio input andoutput components and the video input and output components are showntogether in each of the intelligent lighting devices 11C, one or more ofwhich may be deployed with other lighting devices in some number of theservices areas within premises 21.

Hence, in the example of FIG. 7A, each intelligent lighting device 11Cand/or one or more of the lighting devices 11D includes an audio userinput sensor such as a microphone 35. Any type of microphone configuredto detect audio user input activity, for example, for speech recognitionof verbal commands or the like, may be used; and some other types ofsensors may be used if they provide adequate response to audio input.Although the audio output may be provided in different devices 11; inthe example, each of the intelligent lighting devices 11C or 11D alsoincludes an audio output component such as one or more speakers 37configured to provide information output to the user. Where the speakeris provided in the same or a different device 11, there may be a singlespeaker 37 in each such device 11 or there may be some number ofspeakers in each respective lighting device 11.

The audio input together with lighting control and audio informationoutput implement a form of interactive user interface. Again, the userinterface related operation includes selectively controlling a lightingoperation of at least some number of the lighting devices 11 as afunction of a processed user input. The interface related operation mayalso include either control of a non-lighting-related function as afunction of a processed user input, or an operation to obtain andprovide information as a response to a user input as an output via theoutput component.

Although shown for illustration purposes in the intelligent lightingdevice 11C, image-based input and/or output components may be providedtogether or individually in any others of the lighting devices 11 thatmay be appropriate for a particular installation. Although referred toat times as “video,” the image-based input and/or output may utilizestill image input or output or may use any appropriate form of motionvideo input or output. Hence, in the example of system 10, each ofseveral of the intelligent lighting devices 11D in one or more rooms ofthe premises 21 also supports image input and output for a visual userinterface functionality. Although related audio input and audio outputcould be implemented in other lighting devices, in the example, thedevices 11C also have the microphone 35 and the speaker 37 for the audiobased user interface functionality outlined above.

For the visual user interface functionality, an intelligent lightingdevice 11C includes at least one camera 41. The camera 41 could be astill image pickup device controlled to capture some number of imagesper second, or the camera 41 could be a video camera. By using a numberof cameras 41 to capture images of a given service area, it is possibleto process the image data to detect and track user movement in the area,for example, to identify user input gestures or when a user transitionsfrom one task to another task (e.g., transitioning from reviewingdocuments on a desk to interacting with a computer on the desk) inaddition to or as an alternative to processing of inputs via sensors 31.The multiple cameras 41 could be in a single lighting device 11C orcould be provided individually in two or more of the lighting devicesthat illuminate a particular room or other service area. The imagecapture may also support identification of particular individuals, e.g.via processing of images for face recognition, and associatedcustomization of gesture recognition and/or user responsive systemoperations.

The visual output component in the lighting device 11C is a projector43, such as a pico projector, in this example. The visual outputcomponent may take other forms, such as an integral display as part ofor in addition to the light source. Returning to the example of FIG. 7A,the projector 43 can present information in a visual format, forexample, as a projection on a table or a desk top or a wall or thefloor. Although shown in the same device 11C as the camera 41, theprojector 43 may be in a different intelligent lighting device 11. Also,the projector may be provided in a device 11 in an area that does notutilize a camera 41 for the user input sensor. For example, theprojector 43 may be in a device or in a service area with another device11 that utilizes a microphone (35) or the like as an audio sensor forspoken user input in an area that may also use sensors such as 31 in oneor more devices 11B to detect gestural inputs or other user activity ortask(s).

The combination of image-based input together with lighting control andimage-based and/or audio information output implement a form ofinteractive user interface. Again, the user interface related operationincludes selectively controlling a lighting operation of at least somenumber of the lighting devices 11 as a function of a processed userinput based on the user's profile and/or learned control function. Theinterface related operation may also include either control of anon-lighting-related function as a function of a processed user input,or an operation to obtain and provide information as a response to auser input as an output via the output component.

In the example, one or more of the processors 17 in the lighting devices11 are configured to process user inputs detected by the user inputsensor(s), such as the visual sensors 31, 33, 41, microphone(s) 35and/or light sensors 33. Of course, other non-contact sensingtechnologies may be used (e.g. ultrasound) instead of or in combinationwith the input sensors discussed above. The processing of sensed userinputs, including for learning and profile based control, may relate toand control operations of the lighting devices 11 in one or more areasof the premises 21. For example, the processing may detect spokencommands and/or relevant gestural inputs or other direct and indirectinputs from a user and, based on the learning algorithm and/or userprofile, control lighting devices 11 in an area in which the usercurrently is located. For example, the resulting output control signalsmay serve to turn lights ON/OFF, to raise or lower lighting intensity,to change a color characteristic of any tunable lighting devices 11and/or various combinations of such changes. As other examples, statechanges responsive to the resulting outputs may include changes of anyone or any combination of: light distribution shape, spectral content(without changing color), aperture and/or fixture shape/size, fixtureaim, color and/or luminance uniformity across fixture output, etc.Changes in light output(s) in response to detected user inputs may alsoproduce a repeating pattern or other sequence of changes in any one ormore of the examples or still other lighting related parameters, e.g.,so as to convey information or direct attention or to provide a desiredvariable lighting effect (such as a variable color ‘light show’ or moodlighting). Changes in the lighting in the occupied area of premises 21in response to such sensed user inputs would provide the user with avisual cue as part of the interactive user interface functionality. Theuser inputs also may be processed to control lighting devices 11 servingother areas of the premises 21.

In addition to lighting control functions, such as mentioned here by wayof example, one or more processors 17 in the intelligent lightingdevices 11 may be configured to process direct and/or indirect userinputs so as to enable the system 10 to obtain and present requestedinformation to a user at the premises 21 and/or obtain requested orotherwise relevant information about the user for use and/or processingby system 10, some element within system 10, and/or some other elementor device at the premises 21. By way of an example of such additionaloperations, the system 10 may also enable use of the lighting devices 11to form an interactive user interface portal, for access to otherresources at the premises 21 (e.g., on users computers in other rooms atthe premises) and/or access to outside network resources such as onserver 27 or a remote terminal 29 (e.g. via the WAN 25). Alternatively,or in addition, such obtained information may also be processed as userinputs by one or more processors 17 in the intelligent lighting devices11 to control a lighting function. For example, as described in greaterdetail below, one or more processors 17 may access an on-line service towhich a user is subscribed, such as might be hosted on server 27 (e.g.,Facebook™, Twitter™, etc.), and determine an on-line statuscorresponding to the subscribed user. In this example, such on-linestatus may be processed as an additional user input to enhance theinteractive user interface functionality.

In the example, one or more of the memories 19 store the user inputsdetected by the user input sensor(s) as data set 3 of the learningsystem 100 and one or more of the processors 17 in the intelligentlighting devices 11 are configured to implement the machine learningalgorithm 5 of the learning system 100. In this way, the intelligentlighting devices 11 learn, for example, from the various user inputsdetected by the user input sensor(s) and the one or more processors 17may incorporate such learning into the operations of the system 10 toimplement a lighting control function.

Although shown for illustration purposes in the intelligent lightingdevice 11D, any one or more of the lighting devices 11 may include asensor 39 for detecting operation of the lighting source 13 within therespective device 11. Such a sensor 39 may sense a temperature of thesource 13 or of other component(s) of the device 11D, or a sensor 39 maysense an optical output of the source 13 (e.g. level or colorcharacteristic). The sensor 39 essentially provides feedback as to thestate of the source 13 or other component(s) of the device 11D, whichmay be used as part of the general control of the lighting device(s) 11.By way of an example, where the performance of the source may have aneffect on sensing of user inputs, e.g. when a device 11B or 11C in aparticular service area optically detects gestures or other visual userinputs, source related feedback from sensor 39 may be used to adjustoutput of the source 13 in one or more of the devices illuminating thearea in a manner intended to assist in the detection of the visual userinput (e.g. to ensure adequate illumination for gesture detection).

In a system such as system 10 of FIG. 7A, the lighting devices 11incorporate the elements and provide processing to support aninteractive user interface, for example, that need not require the userto touch or otherwise physically contact an element of the system. Theuser also need not have or operate a separate device, such as asmartphone or other portable terminal device. The lighting devicesthemselves implement the interactive user interface to the lightingsystem, and the user interacts with the lighting system, eitherintentionally or unintentionally, via the lighting devices 11.Furthermore, such interactive user interface is not based solely onintentional user interaction directly with the lighting system. Asdescribed above and in greater detail below, the various sensors 31, 33,35, and 41 may capture, as user inputs, other user activity, eitherintentional or unintentional and involving either direct interactionwith the lighting system for control of the lighting system or indirectinteraction through other objects and/or occupants within the spaceilluminated by the lighting system. In addition, the lighting system mayacquire user inputs from external sources, such as the user's status foran on-line service (e.g., Facebook™, Twitter™, etc.), and, based onthese user inputs from external sources, modify the operation of thelighting system. The lighting system, for example, also learns fromthese current user inputs as well as a collection of prior user inputsto modify the operation of the lighting system via implementation oflearning system 100 of FIG. 2, as described in greater detail below.

The user interface through the lighting device is given by way ofexample. The system 10, however, may also include or supportcommunications for other elements or devices at the premises 21, some ofwhich may even offer alternative user interface capabilities instead ofor in addition to the interactive user interface supported by thelighting devices 11. For example, the intelligence (e.g. processor 17and memory 19) and the communications interface(s) 15 may be implementedin other elements or devices (i.e. control panel) of system 10.Additionally, standalone sensors of the lighting system that areinterconnected to the data communication network of the system mayperform sensing functions analogous to those of sensors 31, 33, 35, 37,39, 41 and/or 43 in the system 10. See, for example, U.S. applicationSer. No. 13/903,330, Filed May 28, 2013 entitled “LIGHTING NETWORK WITHAUTONOMOUS COMMISSIONING”, and U.S. application Ser. No. 13/964,564,Filed Aug. 12, 2013 entitled “LIGHTING ELEMENT-CENTRIC NETWORK OFNETWORKS”, both of which are entirely incorporated by reference.

The system 10 of FIG. 7A may also support wireless communication toother types of equipment or devices at the premises 21, to allow suchother equipment or devices to use the network 23 and/or to communicatewith the lighting devices 11. By way of example, present drawing FIG. 7Atherefore shows one of the lighting devices including a wirelesscommunication interface 15W, for such a purpose. Although shown in 11B,such an interface 15W may instead or in addition be provided in any ofthe other lighting devices 11 in the system 10. Of note for purposes ofthe present discussion of user interface techniques, the wireless linkoffered by the wireless communication interface 15W allows the system 10to communicate with other user interface elements at the premises 21that are not included within lighting devices 11 but which may be usedin addition or as a supplement to the lighting device-centric userinterface that is otherwise the focus of the present discussion.Although there may be any of a wide range of such other types of userinterface elements at any given premises 21, the drawing shows twoexamples, a remote control 47 as an additional input device and atelevision or monitor 49 as an additional output device. The wirelesslink(s) to devices like 47 and 49 may be optical, sonic (e.g. speech),ultrasonic or radio frequency, by way of a few examples.

Any of the various system elements may be implemented using a PC likeapproach based on any known or available microprocessor architecture,such as a Reduced instruction set computing (RISC) using an ARMarchitecture, as commonly used today in mobile devices and otherportable electronic devices, or a microprocessor architecture morecommonly used in computers such as an instruction set architecture(ISA), like those used in Intel microprocessors and the like. Themicroprocessor based approaches are discussed by way of examples, withrespect to FIG. 7B; however, other processor implementations may beused, such as based on a Peripheral Interface Controller (PIC) or othermicrocontroller architecture. Alternative intelligent architectures forthe intelligence of the devices, however, will still include appropriatecommunication interfaces and couplings for light sources and may includeother standardized ports for connections of sensors, user input/outputdevices, etc.

Turning now to the example of FIG. 7B, the drawing depicts animplementation of an intelligent lighting device 11L using amicroprocessor centric architecture. The device 11L is illustrated as anexample of one of the devices 11 as may be used in an overall lightingsystem like system 10 of FIG. 7A. A similar arrangement of lightingdevice 11L, however, may be deployed as an independent/standaloneluminaire without reliance on other devices or elements of apremises-wide system 10.

At a high level, the fixture or other type of lighting device includes alight source, a power supply circuit coupled to a power source, aprocessor, one or more memories and a communication interface; and thedevice will often include one or more sensors. The user interfacecomponents may be separate from the lighting device. The example 11Lincorporates elements for a non-contact user interface portal. To act asa portal, the lighting device will also have one or more standardinterface ports for attachment of elements for providing the desiredtype of user interface. Each port may be for a hardwired connection toany compatible accessory or may provide a wireless link (e.g. WiFi,Zigbee or Bluetooth) for the accessory.

As an example of an implementation of the processors 17, discussed aboverelative to FIG. 7A, the more detailed example of the lighting device11L includes a microprocessor (μP) 123, which serves as the programmablecentral processing unit (CPU) of the lighting device 11L. The μP 123,for example, may be a type of device similar to microprocessors used inservers, in personal computers or in tablet computers, or insmartphones, or in other general purpose computerized devices. Althoughthe drawing shows a single μP 123, for convenience, the lighting device11L may use a multi-processor architecture. The μP 123 in the example isof a type configured to communicate data at relatively high speeds viaone or more standardized interface buses, represented generally by thebus/arrow 124.

The lighting device 11L includes one or more storage devices, which areaccessible by the μP 123 via the bus 124. Although the lighting device11L could include a hard disk drive or other type of disk drive typestorage device, in the example, the device 11L includes one or morememories 125. Typical examples of memories 125 include read only memory(ROM), random access memory (RAM), flash memory and the like. In thisexample, the memory or memories 125 store executable programming for theμP 123, such as programming implementing the machine learning algorithm5 of learning system 100, as well as data, such as data set 3 oflearning system 100, for processing by or resulting from processing ofthe μP 123.

As in earlier examples, the intelligent lighting device 11L includes alight source 13. The source 13 may take the form of an existing fixtureor other luminaire coupled to the other device components, or the source13 may be an incorporated source, e.g. as might be used in a new designor installation. The source 13 may be any type of source that issuitable to the illumination application (e.g. task lighting, broad arealighting, object or personnel illumination, information luminance, etc.)desired for the space or area in which the particular device 11L is orwill be operated which offers desired light output control capabilities(e.g. dimming, color control etc.). Although the source 13 in the device11L may be any suitable type of light source, many such devices willutilize the most modern and efficient sources available, such as solidstate light sources, e.g. LED type light sources. To support colorcontrol, the device may include some number of LEDs of each of two ormore different color characteristics operated via independentlycontrollable driver channels.

Power is supplied to the light source 13 by an appropriate driver 131.The source driver 131 may be a simple switch controlled by the processorof the device 11L, for example, if the source 13 is an incandescent bulbor the like that can be driven directly from the AC current. Power forthe lighting device 11L is provided by a power supply circuit 133 whichsupplies appropriate voltage(s)/current(s) to the source driver 131 topower the light source 13 as well as to the components of the device11L. In the example, the power supply circuit 133 receives electricityfrom alternating current (AC) mains 135, although the lighting devicemay be driven by a battery or other power source for a particularapplication. Although not shown, the device 11L may have or connect to aback-up battery or other back-up power source to supply power for someperiod of time in the event of an interruption of power from the ACmains 135.

The source driver circuit 131 receives a control signal as an input fromthe processor 123 of the device 11L, to at least turn the source 13ON/OFF. Depending on the particular type of source 13 and associateddriver 131, the processor input may control other characteristics of thesource operation, such as dimming of the light output, pulsing of thelight output to/from different intensity levels, color characteristicsof the light output, etc. If the source and/or driver circuit have thecapability, the driver circuit 131 may also provide some informationback as to the operation of the light source 13, e.g. to advise theprocessor 123 of the actual current operating state of the source 13.

The lighting device 11L also includes one or more communicationinterfaces 141. The communication interfaces at least include aninterface configured to provide two way data communication for the μP(and thus for the device 11L) via the network 23. In the example of FIG.7B, each communication interface 141 is of a type having a bus interfaceto enable the interface 141 to communicate internally with the μP 123via the bus 124. The interface 141 that provides the communication linkto the data communications network 23 enables the μP 123 to send andreceive digital data communications through the particular network 23.As outlined earlier, the network 23 may be wired (e.g. metallic oroptical fiber), wireless (e.g. radio frequency or free space optical),sonic or ultrasonic, or a combination of such network technologies; andthe interface 141 to that network 23 in a particular installation of thedevice 11L will correspond to the most advantageous network available(based on considerations such as cost and bandwidth) at the location ofthe installation. Some devices 11L may include multiple interfaces tothe network 23; and or some devices 11L may include interfaces(analogous to the interface 15W discussed earlier) for communicationwith other equipment in the vicinity.

The lighting device 11L in this example further includes a motorizedcontrol 149. Such motorized control 149 allows the lighting device 11Land/or elements within the lighting device 11L (i.e., light source 13,microphone 35, camera 41, sensors 31, 33, 39, etc.) to be moved and/oradjusted. In one example, the motorized control 149, in response to userinput, moves the lighting source 13 back and forth in a swaying fashion,as if to “wave”. The control 149 may adjust source 13 orientation tospotlight and follow a user as the user moves about a room, as anotherexample. In still another example, the motorized control 149 movescamera 41 so as to track the movement of an occupant through the space.

A device like 11A in the FIG. 7A example may have just the components ofdevice 11L discussed to this point in our more detailed example.However, for implementations of devices like 11B to 11C in the FIG. 7Aexample, the device 11L may have one or more user input sensorsconfigured to detect user activity related to user inputs and/or one ormore output components configured to provide information output to theuser. Although the input and output elements and/or such elements ofdifferent types, for convenience, the device 11L shown in FIG. 7Bincludes both input and output components as well as examples of severaltypes of such components.

In the example, the intelligent lighting device 11L includes a number ofoptical sensors, including one of more of the sensors 31 configured fordetection of intensity of received light and to support associatedsignal processing to determine direction of incident light. Theintelligent lighting device 11L in this example also includes anothertype light sensor, such as a sensor 33 or 39. Although only one circuit143 is shown for convenience, the device 11L will include appropriateinput/output interfaces to operate and receive signals from theapplicable sensors 31, 33 and 39 included in the particularimplementation of the device 11L.

A sensor such as 31, 33 or 39 typically includes one or more physicalcondition detectors, which form the actual device that is responsive tothe particular condition to be sensed. The detector(s) may receive adrive signal; and in response to the sensed condition, the detector(s)produces one or more signals having a characteristic (e.g. voltagemagnitude, current or frequency) that is directly related to acharacteristic level of the sensed condition. A sensor such as 31, 33 or39 also includes a detector interface circuit that provides any drivesignal that may be needed by the particular device type of physicalcondition detector. The detector interface circuit also processes theoutput signal from the detector to produce a corresponding output, in astandardized format.

The sensor I/O circuit 143 in turn provides the input and outputinterface to couple the particular sensor(s) 31, 33 or 39 with the othercomponents of the intelligent lighting device 11L. On the side logicallyfacing the bus and processor, the sensor I/O circuitry 143 in theillustrated architecture provides a bus interface that enables the μP123 to communicate with the respective I/O interface circuit 143 via thebus 124. A port for coupling the circuit 143 to the bus 124 may be inaccordance with a standard, such as USB. Although not shown, the sensorI/O circuit 143 may fit a standard interface port on the board formingthe ‘brain’ and communication portion of the device 11L; and/or thesensor I/O circuit 143 may provide physical and electrical connectionsas well as a protocol for the interface with the applicable sensor suchas 31, 33 or 39 in accordance with a standard, to allow use of sensorsby different manufacturers.

The description of the sensors and I/O circuitry are given by way ofexample, and actual implementations may use somewhat differentarrangements. For example, the detector interface circuit referred toabove as part of the sensor may be incorporated in the applicable sensorI/O circuit 143. Each of the circuit(s) 143 may be configured to providethe electrical interface for one, two or more of the respective sensorsvia the associated coupling(s).

In the example, the intelligent lighting device 11L includes amicrophone 35, configured to detect audio user input activity, as wellas an audio output component such as one or more speakers 37 configuredto provide information output to the user. Although other interfaces maybe used, the example utilizes a bus connect audio interface circuit thatis or includes an audio coder/decoder (CODEC), as shown at 145. TheCODEC 145 converts an audio responsive analog signal from the microphone35 to a digital format and supplies the digital audio to the μP 123 forprocessing and/or a memory 125 for storage, via the bus 124. The CODEC145 also receives digitized audio via the bus 124 and converts thedigitized audio to an analog signal which the CODEC 145 outputs to drivethe speaker 37. Although not shown, one or more amplifiers may beincluded to amplify the analog signal from the microphone 35 or theanalog signal from the CODEC 145 that drives the speaker 37.

In the example, the intelligent lighting device 11L also includes acamera 41, configured to detect visible user input activity, as well asan image (still or video) output component such as a projector 43,configured to provide information output to the user in a visual format.The lighting device will also include appropriate input signalprocessing circuitry and video driver circuitry, for example, as shownin the form of a video input/output (I/O) circuit 147. The interface(s)to either one or both of the camera 41 and the projector 43 could beanalog or digital, depending on the particular type of camera andprojector. The video I/O circuit 147 may also provide conversion(s)between image data format(s) used on the bus 124 and by the μP 123 andthe data or signal formats used by the camera 41 and the projector 43.

The actual user interface elements, e.g. speaker and/or microphone orcamera and/or projector, may be in the lighting device 11L or may beoutside the device 11L with some other link to the fixture. If outsidethe lighting device 11L, the link may be a hard media (wire or fiber) ora wireless media.

The device 11L as discussed above and shown in the drawing includes userinterface related components for audio and optical (including image)sensing of user input activities. That intelligent lighting device alsoincludes interface related components for audio and visual output to theuser. These capabilities of the device 11L and the system 10 support aninteractive user interface through the lighting device(s), for example,to control lighting operations, to control other non-lighting operationsat the premises and/or to provide a portal for information access (wherethe information obtained and provided to the user may come from otherequipment at the premises or from network communications withoff-premises systems). In addition, the interactive user interface isenhanced via implementation of the learning system 100 of FIG. 2, asdescribed in greater detail below.

For example, the device 11L and/or the system 10 can provide a voicerecognition/command type interface via the lighting device and networkto obtain information, to access other applications/functions, etc. Forexample, a user can ask for the system to check his/her calendar and/orthe calendar of someone else and can ask the system to schedule ameeting. Furthermore, based on lighting operations during prior meetingsand user activity during the scheduled meeting, device 11L and/or thesystem 10, influenced by learning system 100, may adjust and/orotherwise control lighting operations during the scheduled meeting.

In an initial implementation, the speech is detected and digitized inthe lighting device 11L and is processed to determine that the lightingdevice 11L has received a command or a speech inquiry. For an inquiry,the lighting device 11L sends a parsed representation of the speechthrough the lighting system 10 (and possibly an external network 25) toa server or the like with full speech recognition capability. The serveridentifies the words in the speech and initiates the appropriate action,for example, to turn OFF or otherwise control light source 13. Theserver sends the information back to the lighting device 11L (orpossibly to another device) with the appropriate output capability, forpresentation to the user as an audible or visual output. Any necessaryconversion of the information to speech may be done either at the serveror in the lighting device, depending on the processing capacity of thelighting device. As the processing capacity of lighting devicesincreases, some or all of the functions of the server in this examplemay be shifted into the lighting devices.

The lighting device 11L and the system 10 may provide similar servicesin response to gestural inputs, detected via sensors 31, one or morecameras 41 or a combination of sensors and cameras. Also, systems thatinclude both audio and optical input components can respond tocombinations of speech and gestural inputs. Systems that include bothaudio and video output components can present information to the user(s)in various desirable combinations of audio and image or video outputs.

With an approach like that outlined above, the lighting system maysupport a broad range of applications or functions often performed viaother user terminal devices. For example, the user may be able to postto social media, access social media, send messages via mobile message(e.g. text) or instant messaging or email. The system with the interfaceportal enables the lighting system/service provider or some otheroperator of the system 10 to offer other services, such as informationaccess and personal communication. The lighting device 11 and/or system10 may detect when the user enters the area and provide notices toappropriate ‘friends’ or the like. In addition, as described in greaterdetail below, the lighting system may also capture this informationprovided via the interface portal (i.e., social media status updateand/or message content), utilize the captured information to learn aboutthe user (e.g., current mood, plans, deadlines, etc.) and modify theoperation of the lighting system to reflect the user's current conditionand/or situation.

The interactive user interface implemented by lighting devices 11 and/orlighting system 10 in conjunction with learning system 100 may generallybe referred to as a human/machine user interface. FIG. 8 illustrates afunctional block diagram of an example of such human/machine userinterface. In the example of FIG. 8, human/machine user interface 801includes active sensing 803 and passive sensing 805. Active sensing 803includes, for example, sensing intentional direct user activity such asgestural control 831, voice command 833, control via a smart device 835,and/or control via a control panel 837. Examples of such active sensing803 were described in greater detail above in relation to FIG. 7A.Passive sensing 805 includes, for example, intentional and/orunintentional indirect user activity and/or user status(es) such as taskrecognition 851, biometrics 853, mood determination 855 and/or voicerecognition 859. Stated another way, active sensing 803 involveslighting device(s) 11 and/or lighting system 10 responding directly tosensed user input (e.g., a voice command to turn a lighting device 11off) while passive sensing 805 involves lighting device(s) 11 and/orlighting system 10 utilizing intentional and/or unintentional, directand/or indirect sensed user input as part of a determination related tothe user (e.g., voice recognition sensing frustration in a user's voiceduring a conversation between two occupants of a space). Although somereference to passive sensing 805 was included in the discussion of FIG.7A, greater detail will be provided here and further below.

Task recognition 851 involves, for example, determining a task beingperformed by a user. In one example, image sensor 41 of lighting device11C senses that a user is positioned in front of a user terminal. Basedon this sensed input, task recognition 851 would determine that the useris performing a task involving the user terminal. As a result, lightingdevice 11C may be adjusted to provide a better suited lighting operationfor the user while performing this task. Although the sensed input isrelated to the user and the user is, in this example, intentionallyinteracting with the user terminal, such intentional user activity isnot directed to interaction with lighting device 11C and/or lightingsystem 10. Thus, task recognition 851 is passively sensing the user'sactivity, and lighting device 11C and/or lighting system 10 may beadjusted based on this passive sensing. As a further example, when theuser transitions to reviewing papers on the desk, sensor 31 mightidentify the movement triggering image sensor 41 to capture an image ofthis new activity. Task recognition 851 then utilizes these inputs toidentify this new task and further adjust lighting device 11C and/orlighting system 10 to provide a better suited lighting operation forthis new task.

Biometrics 853 involves, for example, utilizing physical characteristicsin the process of identifying a particular individual. In the example ofFIG. 7A, an occupancy sensor such as sensor 33 of lighting device 11Bidentifies that an occupant has entered a room or space serviced bylighting device 11B. Based on the occupancy sensed by sensor 33,biometrics 853 utilizes, for example, image sensor 41 and microphone 35of lighting device 11C to determine specific characteristics of theoccupant that uniquely identify the occupant (i.e., User A as opposed toUser B). This may involve pattern recognition to identify user features,e.g. face recognition or relative user dimensions in comparison to oneor more objects in a room, etc. Based on the identification provided bybiometrics 853, lighting device(s) 11 and/or lighting system 10 may beadjusted to better suit the preferences of the identified occupant,typically by controlling one or more operations based on a user profileand/or learned preferences via learning system 100.

Voice recognition 859, for example, utilizes acoustics to help identifya particular individual. In this way, voice recognition 859 is similarto and may use or be used by and/or in conjunction with biometrics 853.In addition, voice recognition 859 involves, for example, utilizingacoustical characteristics in the process of identifying the mood and/oractions of one or more occupants within a space. In one example,microphone 35 of lighting device 11C captures the voices of twooccupants within a room or space serviced by lighting device 11C. Voicerecognition 859, utilizing the captured voices, determines that at leastone occupant is agitated and/or that a heated discussion is on-going(e.g., one or both voices are louder than normal). In response, lightingdevice 11C and/or lighting system 10 may be adjusted to influence and/ormitigate the actions of the occupants, for example, by lowering theintensity and/or changing color of the illumination of the room or otherspace occupied by the agitated parties.

Mood determination 855 involves, for example, determining the currentmood of an individual. As depicted in FIG. 8 by the bi-directionalarrows, mood determination 855, for example, utilizes biometrics 853and/or voice recognition 859 as part of the determination process. Mooddetermination 855 may also utilize the current moodscape 856 (i.e.,lighting and/or other conditions in the space that may impact mood) aswell as status updates provided via social media 858. In one example, alighting device 11 and/or the lighting system 10 identifies an occupant,as previously described, and, based on the identification, utilizes theinformation portal discussed above to retrieve on-line status updatesfor the occupant via social media 858. The on-line status updatesindicate the occupant is happy and/or generally in a good mood. At thesame time, based on conditions sensed by various sensors, the lightingdevice 11 and/or lighting system 10 determines the current moodscape 856includes a bright, sunny morning. In addition, voice recognition 859, inthis example, determines that the occupant is whistling. In light ofthis feedback from social media 858, moodscape 856 and voice recognition859, mood determination 855, for example, determines the occupant iscurrently experiencing a good mood and lighting device 11 and/orlighting system 10 are adjusted to reinforce this good mood. Intensityor color etc. of the illumination may change and/or the system maychange one or more other environmental control(s), e.g. set pointtemperature and/or blower speed of a heating, ventilation, and airconditioning (HVAC) component.

The human/machine user interface 801 utilizes active sensing 803 andpassive sensing 805 to implement an enhanced interactive user interfacefor lighting devices 11 and/or lighting system 10. In addition,incorporation of the learning system 100 further enhances theinteractive user interface by allowing the lighting devices 11 and/orlighting system 10 to learn from and adjust operations based uponindividual occupants with a room or space. FIG. 9 illustrates an exampleof a process by which a lighting device 11 and/or a system 10 operateand/or are adjusted based on learning via learning system 100.

In step S91, a lighting device 11 and/or system 10 identifies anoccupant of a room or other type of space serviced by one or morelighting devices 11. As described above, such occupant identificationis, for example, based on biometrics 853 and/or voice recognition 859 aspart of passive sensing 805 of the human/machine user interface 801.Alternatively, or in addition to, such identification may be based onactive sensing 803. For example, lighting device 11 and/or system 10identifies the occupant based on an identifier of the occupant (e.g.,pattern on a badge, a smart badge (e.g., RFID), an identifier emitted bya mobile device, etc.) sensed by and/or otherwise obtained by one ormore of the various sensors or user input elements.

In step S92, the lighting device 11 and/or system 10 retrieves a profilecorresponding to the identified occupant. The profile includes alighting control function established for the identified occupant. Theprofile is initially established, for example, as a preset and/ordefault lighting control function, either by the identified occupant, amanufacturer, an administrator of the lighting system 10 and/or someother individual or entity. Alternatively, or in addition to, theprofile is developed or updated over time by learning via the learningsystem 100, as discussed in greater detail below. The lighting controlfunction defines at least one of a plurality of parameters of visiblelight to be output by a light source 13 (e.g., level, CCT, etc.).Furthermore, the preset and/or default lighting control function definesa set of standardized responses (i.e., corresponding change to at leastone of the plurality of parameters and/or other control of lightingdevice 11) based upon sensed activity. In step S93, the lighting device11 and/or lighting system 10 operate the light source 13 in accordancewith the lighting control function included in the retrieved profile.

Additionally and/or alternatively, such retrieved profile of step S92includes an environmental control function corresponding to anenvironmental condition of the room or other type of space, andcorresponding elements of system 10 are operated in step S93 to controlthe environmental condition in accordance with the environmental controlfunction. For example, if the environmental condition is roomtemperature, the environmental control function operates one or moreHVAC components in setting and maintaining the desired room temperature.As another example, the environmental condition may be the positionand/or transparency of electromechanical window blinds or shades and theenvironmental control function operates the blinds or shades throughoutthe day.

In step S94, the lighting device 11 and/or lighting system 10 determinesat least one status corresponding to the identified occupant of thespace. For example, in step S95, lighting device 11 and/or lightingsystem 10 utilize the information portal to determine a status for theidentified occupant with an on-line service. As discussed above, forexample, mood determination 855 of passive sensing 805 within thehuman/machine user interface 801 utilizes social media 858 to determinethe status for the identified occupant with the on-line social mediaservice. Alternatively, or in addition to step S95, lighting device 11and/or lighting system 10, for example, determines an activity for theidentified occupant in step S96. As discussed above, the human/machineuser interface 801 utilizes, for example, task recognition 851 todetermine such identified occupant activity (e.g., interacting with userterminal, reviewing papers, talking on the phone, moving within thespace, etc.).

As a result of determining the on-line service and/or activity statusesin step S94, the lighting device 11 and/or lighting system 10 adjuststhe lighting control function to control the operation of the lightsource 13 in step S97. In one example, lighting device 11 and/orlighting system 10 determines that the identified occupant recentlyposted a status to an on-line service indicating the identified occupantis upset and/or otherwise frustrated. As a result, lighting device 11and/or lighting system 10 adjusts the control of light source 13 to helpreduce and/or alleviate the identified occupant's frustration based on astandardized response defined by the occupant's profile. In anotherexample, lighting device 11 and/or lighting system 10 determines thatthe identified occupant is conducting a heated telephone conversation.As a result, lighting device 11 and/or lighting system 10 adjusts thecontrol of light source 13 to offset the identified occupant's agitatedstate, once again based on a standardized response defined by theoccupant's profile. In yet another example, lighting device 11 and/orlighting system 10 determines that the identified occupant is conductingthe heated telephone conversation after recently posting to an on-lineservice about being upset and/or otherwise frustrated. As a result,lighting device 11 and/or lighting system 10 adjusts, based on theprofile defined response, the control of light source 13 to both helpreduce and/or alleviate the identified occupant's frustration and offsetthe identified occupant's agitated state. In this way, the system 10discovers or learns “current activity” from and/or about the occupantand responds to such “current activity learning”. In each of theseexamples, the adjustment, although based on “current activity learning”,is predefined and/or standardized based on the occupant's profile.

As in steps S92 and S93, step S97 may additionally and/or alternativelyadjust an environmental control function based on determining theon-line service and/or activity statuses in step S94. In theelectromechanical blinds or shades example, system 10 may determine,based on task recognition 851, that an occupant has placed his or herhead on the desk, in which case the system 10 operates the blinds orshades in such a way as to maximize the amount of sunlight entering theroom or other type of space and encourage the occupant to return toother work activities. Furthermore, the system 10 also adjusts thecontrol of light source 13 to enhance work lighting. Once again, theseresponses by system 10 are, for example, predefined by the occupant'sprofile.

The system in our example ‘learns’ in two ways. The system learns somecurrent inputs and the system learns how best to respond to currentinputs based on a control function ‘learned’ from historicalinformation. The historical learning may use direct user feedback and/orearlier less direct user inputs. Hence, in the examples, suchadjustments in step S97 are based on a determination of one or morecurrent statuses of the identified occupant or “current activitylearning” and a predefined and/or standardized response based on theoccupant's profile. Alternatively, or in addition to, such adjustmentsare based, for example, on a determination of one or more currentstatuses and a determination of one, all, or some combination of priordetermined statuses, in particular, prior determined statuses as aresult of previous predefined and/or standardized responses. Such“historical or feedback based learning” takes prior determined statusesas a result of prior predefined and/or standardized responses asfeedback into the learning system, such as learning system 100.

For example, in the context of FIGS. 2 and 9, learning system 100, aspart of step S97, may take as input the determined activity status thatthe occupant is engaged in a heated telephone conversation (i.e., input1A). The learning system 100, further as part of step S97, may also takeas input the fact, stored in data set 3, that, during a previous heatedconversation when the color characteristics of light source 13 werechanged based on a standardized response (i.e., output 7K), theconversation continued to remain heated while during a similarconversation when the occupant dimmed the light source 13, theconversation returned to normal tones. As a result, learning system 100,in step S97, may provide an output control signal that adjusts the lightsource 13 to be dimmed. In this way, the lighting device 11 and/orlighting system 10 receives prior determined statuses (i.e., discoveredor learned “current activity” in the past) as feedback that allows thelighting device 11 and/or lighting system 10 to learn and modify thepredefined and/or standardized responses based on such learning.

As an additional example of direct feedback, lighting device 11 and/orlighting system 10 is configured to operate in accordance with a presetlighting control function, such as the function described above inrelation to FIGS. 3-6 above. Specifically, lighting device 11 and/orlighting system 10 operates some number of light sources 13, forexample, in a manner that simulates the rise, traversal, and setting ofthe sun throughout a standard work day of 9 AM to 5 PM. In this example,however, an occupant's work day begins at 3 PM and continues untilmidnight. As such, when the system starts to transition the light source13 into the evening hours, the occupant manually adjusts the lightsource 13 to reflect the occupant's modified work day. Over time andbased on “historical or feedback based learning”, lighting device 11and/or system 10 will begin to operate based on a developed or modifiedlighting control function taking into account the occupant's manualadjustments and modified work day.

As a further learning example, in the case of the blinds or shades,system 10 may determine, based on previous activity statusdeterminations, that the occupant regularly places his or her head onthe desk at a similar time each day and for a similarly regular periodof time. In addition, in response to the system 10 opening the shadesand raising the lights on previous occasions, the occupant closes theshades and lowers the lights. In response, the system 10 learns that theoccupant intends for this regular period of time to be a time of rest.As such, as the initial time approaches, system 10 operates the blindsor shades to minimize the amount of sunlight entering the room or othertype of space and adjusts light source 13 to enhance the occupants rest.Then, after the regular period of time, system 10 operates the blinds orshades to maximize sunlight while also adjusting light source 13 torestore optimal working conditions.

That is, the system learns not only the occupants current activity, butalso learns the occupant's previous responses to the system's predefinedand/or standardized responses to similar previous activity as well asthe occupant's previous responses to other conditions and/or situations.Thus, the system 10 learns how to modify the predefined and/orstandardized responses in a personalized fashion, thereby developing orlearning a modified profile associated with the identified occupant. Inthis example, the identified occupant previously made one or more manualadjustments to the lighting control function (i.e., increasing the lightintensity while reviewing papers) corresponding to the lighting device11 and/or lighting system 10 determining one or more previous statusesfor the identified occupant and making an adjustment based on astandardized response (i.e., system 10 previously decreased the lightintensity when task recognition 851 determined the occupant wasreviewing papers). Such manual adjustments serve as feedback that thestandardized response was not appropriate for this particular occupant.Utilizing learning system 100, as described above, lighting device 11and/or lighting system 10 learns from the previous manual adjustmentsand previous determinations to influence the determination of currentstatuses and/or the adjustments to operations of the light source 13(i.e., system 10 now increases the light intensity when task recognition851 determines this occupant is reviewing papers). As such, theadjustments are a result of the current determined statuses, the currentdetermined statuses influenced by previously determined statuses, and/orsimilar user adjustments in similar situations. In this way, the system10 utilizes “historical or feedback based learning” to develop amodified profile for an identified occupant. In addition, system 10utilizes this modified profile or “historical or feedback basedlearning” to respond to “current activity learning” of the identifiedoccupant.

While FIG. 9 depicts an example of a process involving a singleidentified occupant, FIG. 10 illustrates an example of a processinvolving multiple identified occupants for use by the lighting device11 and/or lighting system 10.

In step S101, a lighting device 11 and/or lighting system 10 identifiesoccupants, similar to step S91 of FIG. 9. In some situations, lightingdevice 11 and/or lighting system 10 is able to identify all of theoccupants. In other situations, lighting device 11 and/or lightingsystem 10 may only identify one or more of the occupants. For each ofthe identified occupants in step S101, lighting device 11 and/orlighting system 10 retrieves a profile, established for the identifiedoccupant, including a lighting control function in step S102.

Although not shown, a default profile, including a default lightingcontrol function, is retrieved, for example, for any unidentifiedoccupant. Furthermore, as with FIG. 9, any profile may additionallyand/or alternatively include an environmental control function andlighting device 11 and/or lighting system 10 may operate and/or adjustone or more elements to control an environmental condition of the roomor other type of space. For simplicity, however, the following examplesonly refer to a lighting control function and operation and/oradjustment of the light source 13.

In step S103, operation of the light source 13 is controlled based onthe contribution each retrieved profile makes to a composite profile.For example, each profile contains a weight corresponding to how theretrieved profile contributes to the composite profile. The weight maybe a single weight corresponding to the profile as a whole or the weightmay comprise individual weights corresponding to individual parametersof visible light output controlled by the lighting control function(e.g., level has a corresponding weight, CCT has a corresponding weight,etc.). In some situations, the profile comprises a corresponding weightfor each parameter controlled by the lighting control function. In othersituations, the profile only comprises a corresponding weight for thoseparameters controlled by the lighting control function that differ froma default value. In still other situations, the lighting controlfunction only comprises those parameters for which the lighting controlfunction controls the parameter in variance to some default and theprofile comprises weights for all of those parameters or only somesubset of those parameters.

In one example, the retrieved profile with the highest (or lowest)weight controls and the composite profile is the retrieved profile withsuch weight. In another example, each retrieved profile contributes tothe composite profile proportionally based on the corresponding weight.In such an example, a weighted utility function may be utilized tomaximize or minimize the corresponding contribution of each retrievedprofile.

Utility is an economic term generally referring to the totalsatisfaction received from consuming a good or service. A utilityfunction represents a consumer's preference for an individual item inrelation to a collection of items. Thus, utility functions are utilizedin modeling or theory. In one example, the lighting device 11 and/orlighting system 10 develops a utility function, or preference relation,for each identified occupant. That is, based on the “historicallearning” of learning system 100, lighting device 11 and/or lightingsystem 10 determines each identified occupant's preferences for thevarious parameters controlled by the lighting control function includedin that identified occupant's profile. Further in the example, thelighting device 11 and/or lighting system 10 develops a compositeutility function, or composite preference relation, that incorporatesthe utility function of each identified occupant and the weightcorresponding to each identified occupant's profile (i.e., U=f(U1, U2, .. . , k1, k2)). Finally, lighting device 11 and/or lighting system 10maximizes or minimizes the composite utility function in order todetermine a corresponding lighting control parameter value thatincorporates the weighted preferences of each identified occupant (e.g.,if the corresponding parameter is CCT, an optimal U will minimize theroot mean square (RMS) between the actual value and the weightedpreferences of each identified occupant).

In step S104, lighting device 11 and/or lighting system 10 determinestatuses for each identified occupant, similar to step S94 of FIG. 9. Instep S105, an on-line service status is determined for each identifiedoccupant, if available, and an activity status is determined, in step106, for each identified occupant, if available. As a result ofdetermining one or more statuses for each identified occupant, lightingdevice 11 and/or lighting system 10, in step S107, performs a compositeadjustment. Such composite adjustment is based, similar to step S103, ona contribution by each identified occupant and/or corresponding profile.

Like the example of FIG. 9, the process example of FIG. 10 may utilizethe learning system 100 such that lighting control operations andadjustments are performed based on learning from some combination ofcurrent and/or previous operations and/or adjustments. Although notexplicitly shown, such learning influences, for example, currentoperations and adjustments as well as future operations and adjustments.

FIGS. 9-10 depict examples of processes whereby an established lightingcontrol function is implemented and adjusted based on determinedstatuses of one or more identified occupants. FIG. 11 illustrates anexample process whereby a lighting control function is initiallyestablished and adjusted based on learning.

In step S111, a lighting device 11 and/or lighting system 10 identifiesan occupant of a room or space serviced by lighting device 11. Asdiscussed above, such identification is, for example, via passivesensing 805 and/or active sensing 803. In step S112, a light source 13is operated based on a default profile. In step S113, input is receivedby the lighting device 11 and/or lighting system 10. In one example, theuser provides an input in step S114. Such user input is one of agestural control 831, a voice command 833, control via a smart device835 and/or control via a control panel 837 as part of active sensing 803discussed in greater detail above. In another example, the lightingdevice 11 and/or lighting system 10 utilizes passive sensing 805 todetermine an activity status in step S115. In this example, lightingdevice 11 and/or lighting system 10 utilizes task recognition 851, voicerecognition 859 and/or some other passive sensing to determine anactivity for the identified occupant.

Based on the received input in step S113, operation of the light source13 is modified in step S116. In step S117, a profile corresponding tothe identified occupant and the received input is established andstored. That is, the profile is established based on learningimplemented via learning system 100 by the lighting device 11 and/orlighting system 10. Such learning is based on current user input, instep S114, and/or current determined activity status, in step S115. Asdiscussed above, such learning, in some situations, is also based onpast user input and/or past user activity. In step S118, the storedprofile is retrieved and, in step S119, light source 13 is operatedbased on the retrieved profile. As such, a profile is developed based onlearning by the lighting device 11 and/or lighting system 10 and thelearned profile is retrieved in order to operate a light source 13 inaccordance with the learned profile.

The discussion above has outlined the structure and configuration oflighting devices 11 and systems 10 of such devices as well as severaltechniques for implementing an interactive user interface that relies oninformation retrieval as well as user inputs and learned behavior. Theuser interface could be implemented via processing by as few as one ofthe lighting devices 11. However, many installations will take advantageof processing by a substantial number of the intelligent lightingdevices 11. For complex operations, such as processing of audio oroptical inputs to detect speech or gestural user inputs respectively, itmay also be advantageous to perform some or all of the relevantprocessing using a distributed processing technique.

As shown by the above discussion, at least some functions of devicesassociated or in communication with the networked lighting system 10 ofFIG. 7A, such as elements shown at 27 and 29 (and/or similar equipmentnot shown but located at the premises 21), may be implemented withgeneral purpose computers or other general purpose user terminaldevices, although special purpose devices may be used. FIGS. 12-14provide functional block diagram illustrations of exemplary generalpurpose hardware platforms.

FIG. 12 illustrates a network or host computer platform, as maytypically be used to implement a host or server, such the computer 27.FIG. 13 depicts a computer with user interface elements, as may be usedto implement a personal computer or other type of work station orterminal device, such as the terminal 29 in FIG. 7A, although thecomputer of FIG. 13 may also act as a server if appropriatelyprogrammed. The block diagram of a hardware platform of FIG. 14represents an example of a mobile device, such as a tablet computer,smartphone or the like with a network interface to a wireless link,which may alternatively serve as a user terminal device like 29. It isbelieved that those skilled in the art are familiar with the structure,programming and general operation of such computer equipment and as aresult the drawings should be self-explanatory.

A server (see e.g. FIG. 12), for example, includes a data communicationinterface for packet data communication via the particular type ofavailable network. The server also includes a central processing unit(CPU), in the form of one or more processors, for executing programinstructions. The server platform typically includes an internalcommunication bus, program storage and data storage for various datafiles to be processed and/or communicated by the server, although theserver often receives programming and data via network communications.The hardware elements, operating systems and programming languages ofsuch servers are conventional in nature, and it is presumed that thoseskilled in the art are adequately familiar therewith. Of course, theserver functions may be implemented in a distributed fashion on a numberof similar platforms, to distribute the processing load.

Also, a computer configured as a server with respect to one layer orfunction may be configured as a client of a server in a different layerand/or for a different function. In a similar fashion, a centralfunction or service 57A, 57B implemented as a server functionality onone or more lighting devices 11 with respect to clientprogramming/functionality of other intelligent system elements atpremises 21 may itself appear as a client with respect to a server in adifferent layer and/or for a different function such as with respect toa server 27.

A computer type user terminal device, such as a desktop or laptop typepersonal computer (PC), similarly includes a data communicationinterface CPU, main memory (such as a random access memory (RAM)) andone or more disc drives or other mass storage devices for storing userdata and the various executable programs (see FIG. 13). A mobile device(see FIG. 14) type user terminal may include similar elements, but willtypically use smaller components that also require less power, tofacilitate implementation in a portable form factor. The example of FIG.14 includes a wireless wide area network (WWAN) transceiver (XCVR) suchas a 3G or 4G cellular network transceiver as well as a short rangewireless transceiver such as a Bluetooth and/or WiFi transceiver forwireless local area network (WLAN) communication. The computer hardwareplatform of FIG. 12 and the terminal computer platform of FIG. 13 areshown by way of example as using a RAM type main memory and a hard diskdrive for mass storage of data and programming, whereas the mobiledevice of FIG. 14 includes a flash memory and may include otherminiature memory devices. It may be noted, however, that more moderncomputer architectures, particularly for portable usage, are equippedwith semiconductor memory only.

The various types of user terminal devices will also include varioususer input and output elements. A computer, for example, may include akeyboard and a cursor control/selection device such as a mouse,trackball, joystick or touchpad; and a display for visual outputs (seeFIG. 13). The mobile device example in FIG. 14 touchscreen type display,where the display is controlled by a display driver, and user touchingof the screen is detected by a touch sense controller (Ctrlr). Thehardware elements, operating systems and programming languages of suchcomputer and/or mobile user terminal devices also are conventional innature, and it is presumed that those skilled in the art are adequatelyfamiliar therewith.

Although FIGS. 12-14 in their present form show computers and userterminal devices, generally similar configurations also may be usedwithin other elements of the lighting system 10. For example, oneimplementation of the brain, communication and interface elements of alighting device may utilize an architecture similar to that of one ofthe computers or mobile terminals. As a more specific example, thepersonal computer type hardware in FIG. 13 (except for the keyboard,mouse and display) could serve as the brain and communication elementsof a lighting device, where the input/output interface I/O wouldinterface to an appropriate light driver and to any sensor(s) or otherenhancement input or output device(s) included within the lightingdevice.

If provided on the system 10, additional system elements, such as astandalone sensor or an additional user interface device, they may besimilarly implemented using an architecture like one of the devices ofFIGS. 12-14. For example, an additional other user interface device (UI)might utilize an arrangement similar to the mobile device of FIG. 14,albeit possibly with only one transceiver compatible with the networkingtechnology of the particular premises (e.g. to reduce costs).

As also outlined above, aspects of the interactive user interface andany associated control and/or learning techniques of the lightingdevices 11 may be embodied in programming of the appropriate systemelements, particularly for the processors of intelligent lightingdevices 11. Program aspects of the technology discussed above thereforemay be thought of as “products” or “articles of manufacture” typicallyin the form of executable code and/or associated data (software orfirmware) that is carried on or embodied in a type of machine readablemedium. “Storage” type media include any or all of the tangible memoryof the computers, processors or the like, or associated modules thereof,such as various semiconductor memories, tape drives, disk drives and thelike, which may provide non-transitory storage at any time for thesoftware or firmware programming. All or portions of the programming mayat times be communicated through the Internet or various othertelecommunication networks. Such communications, for example, may enableloading of the software from one computer or processor into another, forexample, from a management server or host computer of the lightingsystem service provider (e.g. implemented like the server computer shownat 27) into any of the lighting devices, etc. of or coupled to thesystem 10 at the premises 21, including programming for individualelement functions, programming for user interface functions andprogramming for distributed processing functions. Thus, another type ofmedia that may bear the software/firmware program elements includesoptical, electrical and electromagnetic waves, such as used acrossphysical interfaces between local devices, through wired and opticallandline networks and over various air-links. The physical elements thatcarry such waves, such as wired or wireless links, optical links or thelike, also may be considered as media bearing the software. As usedherein, unless restricted to non-transitory, tangible “storage” media,terms such as computer or machine “readable medium” refer to any mediumthat participates in providing instructions to a processor forexecution.

It will be understood that the terms and expressions used herein havethe ordinary meaning as is accorded to such terms and expressions withrespect to their corresponding respective areas of inquiry and studyexcept where specific meanings have otherwise been set forth herein.Relational terms such as first and second and the like may be usedsolely to distinguish one entity or action from another withoutnecessarily requiring or implying any actual such relationship or orderbetween such entities or actions. The terms “comprises,” “comprising,”“includes,” “including,” or any other variation thereof, are intended tocover a non-exclusive inclusion, such that a process, method, article,or apparatus that comprises a list of elements does not include onlythose elements but may include other elements not expressly listed orinherent to such process, method, article, or apparatus. An elementproceeded by “a” or “an” does not, without further constraints, precludethe existence of additional identical elements in the process, method,article, or apparatus that comprises the element.

Unless otherwise stated, any and all measurements, values, ratings,positions, magnitudes, sizes, and other specifications that are setforth in this specification, including in the claims that follow, areapproximate, not exact. They are intended to have a reasonable rangethat is consistent with the functions to which they relate and with whatis customary in the art to which they pertain.

While the foregoing has described what are considered to be the bestmode and/or other examples, it is understood that various modificationsmay be made therein and that the subject matter disclosed herein may beimplemented in various forms and examples, and that they may be appliedin numerous applications, only some of which have been described herein.It is intended by the following claims to claim any and allmodifications and variations that fall within the true scope of thepresent concepts.

What is claimed is:
 1. A system, comprising: a processor; a lightsource, the light source being configured to output visible light in amanner permitting control of a plurality of parameters of the visiblelight output, responsive to control by the processor; a sensorconfigured to detect a condition in a space illuminated by the system,the condition relating to a current mood of at least one of a pluralityof occupants when the occupants are within the space, and to provide acondition responsive input to the processor; a data communicationinterface, controlled by the processor, configured for communication ofdata from and to the system over a network; a storage device accessibleby the processor; and a program in the storage device, wherein executionof the program by the processor configures the system to implementfunctions, including functions to: identify at least one of theplurality of occupants; for each identified occupant: retrieve a profileof the identified occupant, the profile including a lighting controlfunction established for the identified occupant; determine a controlsetting for at least one of the plurality of parameters of the visiblelight output from the lighting control function established for theidentified occupant; process the condition responsive input from thesensor or the data from the data communication interface to determinethe current mood of the identified occupant while in the space, thecurrent mood based on at least two of: (i) biometric information of theidentified occupant, (ii) voice recognition of the identified occupant,or (iii) social media status of the identified occupant; and adjust thecontrol setting of the at least one of the plurality of parameters ofthe visible light output in the lighting control function establishedfor the identified occupant based on a combination of both the currentmood and a manual user lighting adjustment from the identified occupantin response to one or more previous mood statuses similar to the currentmood, the manual user lighting adjustment being a correlated colortemperature adjustment and a time of day or a day of week that thecorrelated color temperature adjustment was made by the identifiedoccupant; and operate the light source and adjust the control of the atleast one of the plurality of parameters of the visible light output inaccordance with a composite lighting control function based on eachidentified occupant's contribution to a composite operation of the lightsource and a composite adjustment to the control setting of the at leastone of the plurality of parameters of the visible light output inaccordance with each identified occupant's adjusted lighting controlfunction.
 2. The system of claim 1, further wherein: each retrievedprofile includes a respective weight; and each identified occupant'scontribution to the composite operation of the light source and thecomposite adjustment to the control setting of the at least one of theplurality of parameters of the visible light output in accordance withthe composite lighting control function is based on the respectiveweight.
 3. The system of claim 2, wherein the retrieved profile with thegreatest corresponding weight controls the composite operation of thelight source and the composite adjustment to the control of the at leastone of the plurality of parameters of the visible light output inaccordance with the composite lighting control function.
 4. The systemof claim 2, wherein the contribution of each identified occupant isfurther based on a weighted utility function for each identifiedoccupant and the maximization or minimization of a composite utilityfunction including the weighted utility function for each identifiedoccupant.
 5. The system of claim 1, wherein further execution of theprogram by the processor further configures the system to implementfurther functions, including functions to: for any unidentifiedoccupant, retrieve a default profile, the default profile including adefault lighting control function; determine a control setting for atleast one of the plurality of parameters of the visible light output inaccordance with the default lighting control function; process thecondition responsive input from the sensor or the data from the datacommunication interface to determine the current mood of anyunidentified occupant while in the space based on at least two of: (i)biometric information of the unidentified occupant, (ii) voicerecognition of the unidentified occupant, or (iii) social media statusof the unidentified occupant; based on the current mood of anyunidentified occupant, adjust the control setting of the at least one ofthe plurality of parameters of the visible light output in accordancewith the default lighting control function; and operate the light sourceand adjust the control of the at least one of the plurality ofparameters of the visible light output based on each unidentifiedoccupant's contribution to the composite operation of the light sourceand the composite adjustment to the control setting of the at least oneof the plurality of parameters of the visible light output in accordancewith the composite lighting control function.
 6. The system of claim 1,further comprising a learning module configured to, based on the one ormore previous mood statuses, previous operations, previous adjustmentsand previous contributions, influence the contribution of eachidentified occupant to the composite lighting control function.
 7. Asystem, comprising: a processor; a light source, the light source beingconfigured to output visible light in a manner permitting control of aplurality of parameters of the visible light output, responsive tocontrol by the processor; a sensor configured to detect a condition in aspace illuminated by the system, the condition relating to a currentmood of an occupant when within the space, and to provide a conditionresponsive input to the processor; a user input element, for providinguser input for processing to the processor; a storage device accessibleby the processor; a program in the storage device, wherein execution ofthe program by the processor configures the system to implementfunctions, including functions to: identify a user as the occupant ofthe space illuminated by the system; operate the light source toilluminate the space while the identified occupant is in the space,including control of at least one of the plurality of parameters of thevisible light output in accordance with a predetermined lighting controlfunction; while illuminating the space, receive an input from both of:the identified occupant representing a desired change of at least one ofthe parameters of the visible light output via the user input element;and the sensor representing a current mood of the identified occupantwhile in the space based upon the condition responsive input to theprocessor, the current mood based on biometric information of theidentified occupant or voice recognition of the identified occupant;modify the predetermined lighting control function in accordance withthe received input based on a combination of both the current mood andthe desired change via the user input element from the identifiedoccupant in response to one or more previous mood statuses similar tothe current mood, the desired change including a time of day or a day ofweek that the desired change of the at least one of the parameters ofthe visible light output was made by the identified occupant; store themodified lighting control function in association with an identificationof the occupant in the storage device, as a profile established for theidentified occupant; while the identified occupant is in the space,utilize the identification of the occupant to retrieve the storedprofile; and utilize the retrieved profile to operate the light sourceto illuminate the space while the identified occupant is in the space,including control of at least one of the plurality of parameters of thevisible light output in accordance with the modified lighting controlfunction.
 8. The system of claim 7, wherein: the received input receivedfrom the identified occupant via the user input element or the sensorrepresent an activity status; and the user input element is a controlpanel responsive to tactile input; and the sensor is at least one of: acapacitive sensor; a microphone responsive to audio input; and a cameraor image sensor responsive to motion.
 9. The system of claim 8, whereinthe user input element is integral to the space illuminated by thesystem.
 10. The system of claim 7, wherein: the user input element is anapplication executing on a tablet, a smartphone or other electronicdevice; and the application communicates with the processor over anetwork via a data communication interface of the system.
 11. The systemof claim 7, wherein the sensor is configured to detect, as thecondition, one or more conditions selected from the group consisting of:an image of the space; audio within the space; motion of the occupantwithin the space; and light from the occupant within the space.
 12. Thesystem of claim 7, further comprising a learning module configured toimplement the function to modify the predetermined lighting controlfunction responsive to the received input based upon previously receivedinputs.
 13. The system of claim 12, wherein: the learning modulecomprises a neural network; the neural network receives the receivedinput and previously received inputs; the neural network produces aweight corresponding to the received input based on the previouslyreceived inputs; and the function to modify the predetermined lightingcontrol function responsive to the received input is based on thereceived input and corresponding weight.
 14. A system, comprising: aprocessor; a light source, the light source being configured to outputvisible light in a manner permitting control of a plurality ofparameters of the visible light output, responsive to control by theprocessor; a sensor configured to detect a condition in a spaceilluminated by the system, the condition relating to a current mood ofan occupant when within the space, and provide the current mood to theprocessor; a storage device accessible by the processor; and a programin the storage device, wherein execution of the program by the processorconfigures the system to implement functions, including functions to:identify at least one of the plurality of occupants; for each identifiedoccupant: retrieve a profile of the identified occupant, the profileincluding a lighting control function established for the identifiedoccupant; determine the current mood of the identified occupant while inthe space, the current mood based on at least two of: (i) biometricinformation of the identified occupant, (ii) voice recognition of theidentified occupant, or (iii) social media status of the identifiedoccupant; and adjust a control setting of at least one of the pluralityof parameters of the visible light output in the lighting controlfunction established for the identified occupant based on a combinationof both the current mood and a manual user lighting adjustment from theidentified occupant in response to one or more previous mood statusessimilar to the current mood, the manual user lighting adjustment being acorrelated color temperature adjustment and a time of day or a day ofweek that the correlated color temperature adjustment was made by theidentified occupant; and operate the light source based on eachidentified occupant's contribution to a composite operation of the lightsource in accordance with a composite lighting control function.
 15. Thesystem of claim 14, further wherein: each retrieved profile includes arespective weight; and each identified occupant's contribution to thecomposite operation of the light source in accordance with the compositelighting control function is based on the respective weight.
 16. Thesystem of claim 15, wherein the identified occupant only contributes tothe composite operation of the light source in accordance with thecomposite lighting control function when the corresponding occupant'sprofile weight is the greatest.
 17. The system of claim 15, wherein thecontribution of each identified occupant is further based on a weightedutility function for each identified occupant and the maximization orminimization of a composite utility function including the weightedutility function for each identified occupant.
 18. The system of claim14, wherein further execution of the program by the processor furtherconfigures the system to implement further functions, includingfunctions to: for any unidentified occupant, retrieve a default profile,the default profile including a default lighting control function;determine a control setting for at least one of the plurality ofparameters of the visible light output in accordance with the defaultlighting control function; and operate the light source based on anyunidentified occupant's contribution to the composite operation of thelight source in accordance with the composite lighting control function.19. The system of claim 14, further comprising a learning moduleconfigured to, based on previous operations and previous contributions,influence the contribution of each identified occupant to the compositelighting control function.